Your search keyword '"Relaxed micromorphic model"' showing total 2 results

1. Microstructure-related Stoneley waves and their effect on the scattering properties of a 2D Cauchy/relaxed-micromorphic interface.

Author

Aivaliotis, Alexios, Daouadji, Ali, Barbagallo, Gabriele, Tallarico, Domenico, Neff, Patrizio, and Madeo, Angela

Subjects

*SCATTERING (Physics), *TRANSMISSION zeros, *BOUNDARY value problems, *ELASTIC waves, *METAMATERIALS, *FLUX (Energy)

Abstract

In this paper we set up the full two-dimensional plane wave solution for scattering from an interface separating a classical Cauchy medium from a relaxed micromorphic medium. Both media are assumed to be isotropic and semi-infinite to ease the semi-analytical implementation of the associated boundary value problem. Generalized macroscopic boundary conditions are presented (continuity of macroscopic displacement, continuity of generalized tractions and, eventually, additional conditions involving purely microstructural constraints), which allow for the effective description of the scattering properties of an interface between a homogeneous solid and a mechanical metamaterial. The associated "generalized energy flux" is introduced so as to quantify the energy which is transmitted at the interface via a simple scalar, macroscopic quantity. Two cases are considered in which the left homogeneous medium is "stiffer" and "softer" than the right metamaterial and the transmission coefficient is obtained as a function of the frequency and of the direction of propagation of the incident wave. We show that the contrast of the macroscopic stiffnesses of the two media, together with the type of boundary conditions, strongly influence the onset of Stoneley (or evanescent) waves at the interface. This allows for the tailoring of the scattering properties of the interface at both low and high frequencies, ranging from zones of complete transmission to zones of zero transmission well beyond the band-gap region. • Stoneley waves at high frequencies are related to the metamaterial's microstructure. • Wide frequency bounds where total reflection or transmission occur can be tailored. • This could produce almost perfect total screens, which do not transmit elastic waves. [ABSTRACT FROM AUTHOR]

Published

2019

2. Towards the conception of complex engineering meta-structures: Relaxed-micromorphic modelling of low-frequency mechanical diodes/high-frequency screens.

Author

Rizzi, Gianluca, Tallarico, Domenico, Neff, Patrizio, and Madeo, Angela

Subjects

*MECHANICAL models, *METAMATERIALS, *ENGINEERING, *SEMICONDUCTOR lasers

Abstract

In this paper we show that an enriched continuum model of the micromorphic type (Relaxed Micromorphic Model) can be used to model metamaterials' response in view of their use for meta-structural design. We focus on the fact that the reduced model's structure, coupled with the introduction of well-posed interface conditions, allows us to easily test different combinations of metamaterials' and classical-materials bricks, so that we can eventually end-up with the conception of a meta-structure acting as a mechanical diode for low/medium frequencies and as a total screen for higher frequencies. Thanks to the reduced model's structure, we are also able to optimize this meta-structure so that the diode-behaviour is enhanced for both "pressure" and "shear" incident waves and for all possible angles of incidence. • The importance of disposing of a reduced model to enable the effective use of metamaterials in meta-structural design. • An enriched continuum model of the micromorphic type can be effectively used to model metamaterials' response, even for specimens of finite size. • The reduced model's structure, coupled with the introduction of well-posed interface conditions allows us to unveil the response of meta-structures combining metamaterials and classical-materials bricks. • The conception of a simple metamaterial/classical-material structure that acts as a mechanical diode for low/medium frequencies and as a total screen for higher frequencies. [ABSTRACT FROM AUTHOR]

Published

2022